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Literature DB >> 34657149

Tyrosine phosphatases regulate resistance to ALK inhibitors in ALK+ anaplastic large cell lymphoma.

Elif Karaca Atabay¹, Carmen Mecca¹, Qi Wang¹, Chiara Ambrogio², Ines Mota¹, Nina Prokoph³, Giulia Mura², Cinzia Martinengo², Enrico Patrucco², Giulia Leonardi¹, Jessica Hossa¹, Achille Pich², Luca Mologni⁴, Carlo Gambacorti-Passerini⁴, Laurence Brugières⁵, Birgit Geoerger^5,6, Suzanne D Turner^3,7, Claudia Voena², Taek-Chin Cheong¹, Roberto Chiarle^1,2.

Abstract

Anaplastic large cell lymphomas (ALCLs) frequently carry oncogenic fusions involving the anaplastic lymphoma kinase (ALK) gene. Targeting ALK using tyrosine kinase inhibitors (TKIs) is a therapeutic option in cases relapsed after chemotherapy, but TKI resistance may develop. By applying genomic loss-of-function screens, we identified PTPN1 and PTPN2 phosphatases as consistent top hits driving resistance to ALK TKIs in ALK+ ALCL. Loss of either PTPN1 or PTPN2 induced resistance to ALK TKIs in vitro and in vivo. Mechanistically, we demonstrated that PTPN1 and PTPN2 are phosphatases that bind to and regulate ALK phosphorylation and activity. In turn, oncogenic ALK and STAT3 repress PTPN1 transcription. We found that PTPN1 is also a phosphatase for SHP2, a key mediator of oncogenic ALK signaling. Downstream signaling analysis showed that deletion of PTPN1 or PTPN2 induces resistance to crizotinib by hyperactivating SHP2, the MAPK, and JAK/STAT pathways. RNA sequencing of patient samples that developed resistance to ALK TKIs showed downregulation of PTPN1 and PTPN2 associated with upregulation of SHP2 expression. Combination of crizotinib with a SHP2 inhibitor synergistically inhibited the growth of wild-type or PTPN1/PTPN2 knock-out ALCL, where it reverted TKI resistance. Thus, we identified PTPN1 and PTPN2 as ALK phosphatases that control sensitivity to ALK TKIs in ALCL and demonstrated that a combined blockade of SHP2 potentiates the efficacy of ALK inhibition in TKI-sensitive and -resistant ALK+ ALCL.

Entities: Chemical

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Year: 2022 PMID： 34657149 PMCID： PMC8814675 DOI： 10.1182/blood.2020008136

Source DB: PubMed Journal: Blood ISSN： 0006-4971 Impact factor: 22.113

82 in total

1. Abrupt Relapse of ALK-Positive Lymphoma after Discontinuation of Crizotinib.

Authors: Carlo Gambacorti-Passerini; Lara Mussolin; Laurence Brugieres
Journal: N Engl J Med Date: 2016-01-07 Impact factor: 91.245

2. Mutation analysis of the tyrosine phosphatase PTPN2 in Hodgkin's lymphoma and T-cell non-Hodgkin's lymphoma.

Authors: Maria Kleppe; Thomas Tousseyn; Eva Geissinger; Zeynep Kalender Atak; Stein Aerts; Andreas Rosenwald; Iwona Wlodarska; Jan Cools
Journal: Haematologica Date: 2011-07-26 Impact factor: 9.941

3. Multi-gene epigenetic silencing of tumor suppressor genes in T-cell lymphoma cells; delayed expression of the p16 protein upon reversal of the silencing.

Authors: T Nagasawa; Q Zhang; P N Raghunath; H Y Wong; M El-Salem; A Szallasi; M Marzec; P Gimotty; A H Rook; E C Vonderheid; N Odum; M A Wasik
Journal: Leuk Res Date: 2005-09-26 Impact factor: 3.156

4. PTPN2 attenuates T-cell lymphopenia-induced proliferation.

Authors: Florian Wiede; Nicole L La Gruta; Tony Tiganis
Journal: Nat Commun Date: 2014 Impact factor: 14.919

5. Identification of a new subclass of ALK-negative ALCL expressing aberrant levels of ERBB4 transcripts.

Authors: Irene Scarfò; Elisa Pellegrino; Elisabetta Mereu; Ivo Kwee; Luca Agnelli; Elisa Bergaggio; Giulia Garaffo; Nicoletta Vitale; Manuel Caputo; Rodolfo Machiorlatti; Paola Circosta; Francesco Abate; Antonella Barreca; Domenico Novero; Susan Mathew; Andrea Rinaldi; Enrico Tiacci; Sara Serra; Silvia Deaglio; Antonino Neri; Brunangelo Falini; Raul Rabadan; Francesco Bertoni; Giorgio Inghirami; Roberto Piva
Journal: Blood Date: 2015-10-13 Impact factor: 22.113

6. ALK inhibitors in non-small cell lung cancer: how many are needed and how should they be sequenced?

Authors: Alice T Shaw
Journal: Clin Adv Hematol Oncol Date: 2017-12

7. SHP2 inhibition restores sensitivity in ALK-rearranged non-small-cell lung cancer resistant to ALK inhibitors.

Authors: Leila Dardaei; Hui Qin Wang; Manrose Singh; Paul Fordjour; Katherine X Shaw; Satoshi Yoda; Grainne Kerr; Kristine Yu; Jinsheng Liang; Yichen Cao; Yan Chen; Michael S Lawrence; Adam Langenbucher; Justin F Gainor; Luc Friboulet; Ibiayi Dagogo-Jack; David T Myers; Emma Labrot; David Ruddy; Melissa Parks; Dana Lee; Richard H DiCecca; Susan Moody; Huaixiang Hao; Morvarid Mohseni; Matthew LaMarche; Juliet Williams; Keith Hoffmaster; Giordano Caponigro; Alice T Shaw; Aaron N Hata; Cyril H Benes; Fang Li; Jeffrey A Engelman
Journal: Nat Med Date: 2018-03-05 Impact factor: 53.440

8. Identification of a nuclear Stat1 protein tyrosine phosphatase.

Authors: Johanna ten Hoeve; Maria de Jesus Ibarra-Sanchez; Yubin Fu; Wei Zhu; Michel Tremblay; Michael David; Ke Shuai
Journal: Mol Cell Biol Date: 2002-08 Impact factor: 4.272

9. Identification of new substrates of the protein-tyrosine phosphatase PTP1B by Bayesian integration of proteome evidence.

Authors: Emanuela Ferrari; Michele Tinti; Stefano Costa; Salvatore Corallino; Aurelio Pio Nardozza; Andrew Chatraryamontri; Arnaud Ceol; Gianni Cesareni; Luisa Castagnoli
Journal: J Biol Chem Date: 2010-12-01 Impact factor: 5.157

Tyrosine phosphatases regulate resistance to ALK inhibitors in ALK+ anaplastic large cell lymphoma.

1. Abrupt Relapse of ALK-Positive Lymphoma after Discontinuation of Crizotinib.

2. Mutation analysis of the tyrosine phosphatase PTPN2 in Hodgkin's lymphoma and T-cell non-Hodgkin's lymphoma.

3. Multi-gene epigenetic silencing of tumor suppressor genes in T-cell lymphoma cells; delayed expression of the p16 protein upon reversal of the silencing.

4. PTPN2 attenuates T-cell lymphopenia-induced proliferation.

5. Identification of a new subclass of ALK-negative ALCL expressing aberrant levels of ERBB4 transcripts.

6. ALK inhibitors in non-small cell lung cancer: how many are needed and how should they be sequenced?

7. SHP2 inhibition restores sensitivity in ALK-rearranged non-small-cell lung cancer resistant to ALK inhibitors.

8. Identification of a nuclear Stat1 protein tyrosine phosphatase.

9. Identification of new substrates of the protein-tyrosine phosphatase PTP1B by Bayesian integration of proteome evidence.

10. Differential expression analysis of multifactor RNA-Seq experiments with respect to biological variation.

Review 1. Protein tyrosine kinase inhibitor resistance in malignant tumors: molecular mechanisms and future perspective.

Review 2. Resistance to Targeted Agents Used to Treat Paediatric ALK-Positive ALCL.

Review 3. Holistic View of ALK TKI Resistance in ALK-Positive Anaplastic Large Cell Lymphoma.

Review 4. Protein Tyrosine Phosphatases in Neuroblastoma: Emerging Roles as Biomarkers and Therapeutic Targets.